KR100951578B1 - Ozone water treatment system using lower energy - Google Patents

Abstract

The present invention relates to an ozone water treatment system using low energy.

The present invention provides a water supply pipe which feeds raw water to be treated with energy; A membrane gas injector for dispersing and injecting ozone gas into ultrafine bubbles into raw water supplied from the water pipe; A low energy usage type gas-liquid contacting reactor for promoting a contact reaction between the raw water and the ozone gas in the ozone mixed water supplied and transported from the membrane gas injector; And a discharge pipe for continuously transporting and discharging the treated water to be reacted.

Therefore, since the use of energy at the time of ozone gas injection and the contact reaction can be greatly reduced, there is an effect that the treatment cost can be reduced.

Ozone, water treatment, energy

Description

Ozone water treatment system using low energy {OZONE WATER TREATMENT SYSTEM USING LOWER ENERGY}

The present invention relates to an ozone water treatment system using low energy, and more particularly, to an ozone water treatment system using low energy, which consumes low energy and can reduce treatment costs and has excellent treatment efficiency.

In general, a water treatment method using ozone (O ₃ ) is to perform high water purification treatment, water and sewage treatment, sewage and wastewater treatment, leachate treatment and the like using the strong oxidizing power, decomposition power, sterilization power, decolorization power and deodorizing power of ozone.

In the water treatment field using the ozone gas, the polluted water is purified through reactions such as the injection, contact, and dissolution of the ozone gas, and specifically, an acid method, an injector method, a pressure pump method, a turbine mixer method, U tube type.

Among these, the acid method is a method in which ozone gas is diffused into fine bubbles by using a diffuser in contaminated water, and fine water is generated at a deep acid depth to perform water treatment.

However, the diffuser method has disadvantages such as blockage of microbubbles, difficulty in controlling bubble size, occurrence of disconnection and channeling, and contact with gas-liquid only through vertical rise due to buoyancy of microbubbles. Because of this, contact and dissolution reactions are poor, ozone utilization is very low due to a decrease in ozone absorption rate and expansion of self-decomposition, and high exhaust ozone concentration causes environmental pollution. Rarely used.

In addition, in recent years, there is a tendency to use a lot of injector method, the injector method is excessive energy loss when inhaling ozone gas in the injector, can not inhale more than a predetermined amount of ozone gas, and also after inhalation in the injector to the subsequent process A static mixer is used for the contact reaction. The static mixer causes a large energy loss, thus consuming a large amount of energy in water treatment, resulting in low energy efficiency and low processing efficiency.

The present invention has been devised to solve the above-mentioned problems, and reduces the use of energy when injecting ozone gas into raw water to be treated and when reacting raw water and ozone gas after injection, thereby reducing treatment costs and improving practicality. The object is to provide an ozone water treatment system using low energy that can be improved.

In addition, the object of the present invention is to provide an ozone water treatment system that uses low energy to maximize the contact reaction between raw water and ozone gas, thereby improving ozone utilization efficiency and providing a perfect water treatment.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The ozone water treatment system using the low energy of the present invention for achieving the above object, the water supply pipe to which the raw water to be treated is transported with energy; A membrane gas injector for dispersing and injecting ozone gas into ultrafine bubbles into raw water supplied from the water pipe; A low energy usage type gas-liquid contacting reactor for promoting a contact reaction between the raw water and the ozone gas in the ozone mixed water supplied and transported from the membrane gas injector; And a discharge pipe for continuously transporting and discharging the treated water to be reacted.

Preferably, the low energy use gas-liquid contact reactor, may be made of any one or more combinations selected from a plate-shaped mixing reactor, multiple injection reactor, split shear reactor.

Also preferably, the raw water supplied through the water pipe may be pressurized by the potential energy caused by the free fall.

In addition, preferably, a water pump for imparting energy and water to the raw water; may further include.

Also preferably, the raw water tank for storing the raw water and supply to the water pipe; may further include.

Also preferably, an ozone generator for generating and supplying the ozone gas to be supplied to the membrane gas injector; And an ozone supply pipe which transfers the ozone gas supplied from the ozone generator to the membrane gas injector and supplies the ozone gas.

Also preferably, the discharge tank for storing the treated water discharged from the discharge pipe; And injection means provided at an end of the discharge pipe to inject the treated water into the water in the discharge tank.

Also preferably, the main reactor for promoting the contact reaction of the raw water and the ozone gas in the ozone mixed water supplied from the low-energy used gas-liquid contact reactor and supplying the treated water treated with reaction to the discharge pipe; can do.

Also preferably, the low energy use gas-liquid contact reactor may be provided in the order of the plate-shaped mixing reactor, the multiple injection reactor, the split shear reactor, and the multiple injection reactor.

Also preferably, the main reactor may include: a spray reverse mixing reactor for injecting and countercurrently mixing the ozone mixed water to generate a contact reaction; And a reaction tank containing the treated reverse mixing reactor and accommodating and discharging the treated water discharged from the spray reverse mixing reactor.

Also preferably, a low-energy use type gas-liquid contacting reactor embedded in the reaction tank and contacting the ozone mixed water and then discharged to the spray reverse mixing reactor may further include a.

Also preferably, the injection reverse mixing reactor may include: an injection pipe in which a front end of the ozone mixed water inflow is opened and a rear end of the outflow end is reduced in cross section so that injection holes are formed in a central portion thereof; And a rear pipe having a concave reflector formed at a rear end thereof so as to counter-flow the ozone mixed water injected from the injection pipe and having a discharge port for discharging the treated water on one side thereof.

Also preferably, the membrane gas injector may include: a main pipe configured to internally transport the raw water supplied from the water pipe; And a porous tube provided in the main pipe and spraying the ozone gas supplied through the plurality of injection holes into the water of the raw water in the form of ultra-fine bubbles.

Also preferably, the plate-shaped mixing reactor, the inlet reduction tube is provided in a form that is gradually reduced in diameter to change the flow path and the flow rate of the ozone mixed water supplied from the membrane gas injector; A rear pipe for internally transferring the ozone mixed water supplied from the inflow reduction tube; And a protruding member provided on the inner side surface of the rear pipe so as to protrude and change the direction and flow rate of the ozone mixed water, and contact the split and shear.

Also preferably, the multi-injection reactor may include: a main pipe configured to internally transport the ozone mixed water; And a blocking porous plate provided in the main pipe in a direction orthogonal to the flow direction of the ozone mixed water and having a plurality of through holes through which the ozone mixed water passes.

Also preferably, the split shear reactor may include: a main pipe for internally transferring the ozone mixed water; And a spiral blade having a curved plate shape which is repeatedly provided in the main pipe along the longitudinal direction.

Also preferably, the circulation pipe branched in the middle of the discharge pipe for transferring a portion of the treated water to the raw water tank side for reprocessing; And a mixed feeder for mixing the treated water supplied through the circulation pipe and the raw water supplied from the raw water tank and supplying the mixed water to the water supply pipe.

Also preferably, the mixing feeder may include: a mixing pipe configured to mix the treated water and the raw water while transferring the internal water; And a strainer provided in the mixing pipe to filter foreign matter.

According to the present invention, it is possible to significantly reduce the use of energy at the time of ozone gas injection and contact reaction can be achieved the effect of reducing the processing cost.

In addition, by using a combination of low energy use type and high efficiency reactors and reprocessing a part of the treated water, the effect of achieving a perfect water treatment using a small amount of ozone can be achieved.

In addition, as the rapid processing is possible, the effect of improving the processing productivity can be achieved.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an ozone water treatment system using a low energy according to a preferred embodiment of the present invention.

According to the present invention, by using the membrane gas injector 140 for the injection of ozone gas into the raw water to be treated, while reducing the energy use during the injection of ozone gas, plate mixing reactor 170, multiple injection reactor 180 By using a combination of low-energy used gas-liquid contact reactors such as the split shear reactor 190 and the spray reverse mixing reactor 200, the energy use in the contact reaction is also reduced, compared to the conventional injector and static mixer combination methods. It will reduce your energy use by 50-60%.

Accordingly, since only a minimum amount of energy is used, the water supply pump 130 for supplying energy to the raw water can be omitted or used with a low capacity, and the water treatment is performed using only the stored potential energy of the raw water without using the water supply pump 130. May be performed.

In addition, after the partial contact reaction is performed in the membrane gas injector 140, the plate-type mixing reactor 170, the multi-injection reactor 180, the split shear reactor 190, the injection reverse mixing reactor 200, which is low energy-use type and excellent in efficiency. ) Can be used in combination to promote contact reaction, improve the ozone utilization efficiency to 99% or more, and complete purification treatment, even raw water containing hardly decomposable substances that can not be treated conventionally In addition, the amount of residual ozone can be reduced, and the amount of ozone used can also be reduced by 20-30% compared to the past, thereby reducing the cost of generating ozone.

The ozone water treatment system according to the present invention includes a raw water tank 110 for storing and supplying raw water to be treated, a water pipe 120 for transferring raw water supplied from the raw water tank 110, and energy required for water treatment to the raw water. The water supply pump 130 to supply and pressurize the raw water, the ozone generator 160 for generating and supplying ozone gas of a suitable concentration to be injected into the raw water to be transferred, and the ozone gas supplied from the ozone generator 160 is transferred. From the membrane gas injector 140 and the membrane gas injector 140 for dispersing and injecting the ozone gas supplied through the ozone supply pipe 165 and the ozone gas supplied through the ozone supply pipe 165 in the form of ultra-fine bubbles into the raw water transported therein. A low-energy used gas-liquid contacting reactor that promotes a gas-liquid contact reaction between raw water and ozone gas in the supplied and transported ozone mixed water, followed by The main reactor 230 to nearly complete the reaction to facilitate the catalytic reaction, and includes a discharge pipe 240 for transporting effluent to the reaction process can be treated discharged from the main reactor 230.

Raw water tank 110 is to supply the raw water to be treated to temporarily store and then supply, to overcome the fluctuations in the inflow of raw water and select the capacity to operate the system stably.

One side of the raw water tank 110 is provided with a discharge port for discharging the raw water, the discharge port is connected in communication with one end of the water pipe (120).

Here, although the raw water may be supplied directly through the water supply pipe 120 without the raw water tank 110, it is preferable that the raw water tank 110 is provided for stable supply of raw water.

Water supply pipe 120 is a pipe for internally transporting the raw water supplied from the raw water tank 110 to supply, one end is connected to the outlet of the raw water tank 110 and the other end is connected to the tip of the membrane gas injector 140 to feed the raw water. Supply to membrane gas injector 140.

The water pipe 120 is designed and provided to minimize the energy loss of the raw water being delivered.

The water pump 130 supplies energy required for water treatment to the raw water so that the raw water is sucked and pressurized at a constant pressure and flow rate, and selects and uses an excellent operating efficiency at the flow rate and the head.

According to the present invention, since the water can be smoothly treated even if only a small amount of energy is supplied to the raw water, the water pump 130 for supplying energy to the raw water can be omitted or used with a small capacity, without using the water pump 130. The raw water may be supplied with only potential energy due to the drop, and in this case, the provision of the drop energy may be implemented by providing the water pipe 120 to be vertical.

The ozone generator 160 generates and supplies ozone gas having an appropriate concentration and capacity to be injected into the raw water to be transported, and receives ozone from a separate source gas tank 150 to generate ozone.

When the source gas is oxygen or dry air, the ozone generator 160 passes the source gas supplied at a predetermined pressure state through an electric field, where some of the oxygen molecules are separated into oxygen atoms, and the separated oxygen atoms are separated from other oxygen molecules. Ozone can be generated by being combined with.

The source gas tank 150 supplies the source gas necessary for ozone generation to the ozone generator 160, and the source gas may be oxygen or dry air.

The ozone supply pipe 165 internally transfers the ozone gas supplied from the ozone generator 160 to supply the membrane gas injector 140, one end of which is connected to the ozone generator 160 and the other end of which is connected to the membrane gas injector 140. do.

The ozone supply pipe 165 may be properly designed to protect the ozone generator 160 by preventing backflow of raw water from the membrane gas injector 140 due to a temporary mismatch of raw water feed pressure.

Of course, a separate backflow prevention means (not shown) such as a check valve may be provided on the ozone supply pipe 165 to more completely block backflow of raw water.

Meanwhile, the source gas tank 150 and the ozone supply pipe 165 are directly connected to supply the source gas in a high pressure state directly to the membrane gas injector 140 at a necessary time, thereby contaminating and clogging the membrane gas injector 140. Raw material gas supply pipe 155 is provided for solving and maintaining.

The membrane gas injector 140 disperses the ozone gas into the water of the raw water to be transported internally using its own pressure of the ozone gas supplied through the ozone supply pipe 165.

Specifically, as shown in FIG. 2, the membrane gas injector 140 includes a main pipe 144 for internally transferring raw water supplied from the water pipe 120 and a small diameter pipe in the main pipe 144. The porous tube 146 which sprays ozone gas underwater in the form of ultra-fine bubbles through numerous ultra-fine injection holes 146a formed on the outer surface thereof, the external ozone supply pipe 165 and the internal porous pipe 146. It is made of a gas connection pipe 142 for supplying ozone gas by connecting the.

Here, the main pipe 144 is open at both ends, the both ends are formed with a flange portion (144a) for pipe connection.

In addition, the porous tube 146 is sprayed to make the ozone gas in the form of ultra-fine bubbles to be dispersed, it is provided long along the longitudinal direction as shown, a plurality can be provided to be evenly arranged.

The porous pipe 146 is provided to be closed except for a portion connected to the gas connection pipe 142, and the ultra-fine injection holes 146a are disposed on the outer surface of the porous pipe 146 so as to be uniformly disposed throughout.

Therefore, since the ozone gas is injected into the ultra-foamed bubble through the numerous ultra-fine injection holes 146a, the ultra-fine bubbles of the ozone gas can be quickly and uniformly mixed and dissolved in the raw water transported therein. Contact reaction between raw water and ozone gas can be maximized.

By using the membrane gas injector 140, the pressure loss of the injected ozone gas can be realized at 200 mbar or less, and above all, it is possible to minimize the energy use of the raw water according to the ozone gas injection, that is, the existing injector Compared to the use, the energy consumption of raw water can be reduced by 1/20.

Preferably, the size of each ultra-fine injection hole (146a) formed on the porous tube 146 to minimize energy use and maximize the mixing and contact reaction may be implemented to 10㎛ or less.

The low energy use gas-liquid contact reactor promotes the contact reaction between the raw water and the ozone gas while minimizing the energy use of the ozone mixed water to be transported. Specifically, the plate-type mixing reactor 170, the multiple injection reactor 180 and the split shear reactor ( 190).

The plate mixing reactor 170 changes the flow path of the ozone mixed water, accelerates the flow rate, and splits and shears the ozone mixed water to promote the contact reaction.

As shown in FIG. 3, the plate-shaped mixing reactor 170 is provided in the form of a tube which gradually decreases in diameter to reduce the flow rate of the ozone mixed water supplied and transported from the membrane gas injector 140 and accelerate the flow rate. A plurality of pipes 172, a rear pipe 174 for continuously transferring ozone mixed water after the inflow reduction tube 172, and a plurality of protrusions are provided so as to protrude on the inner side of the rear pipe 174, the direction of the ozone mixed water. And a protruding member 176 that causes turbulence by changing the flow rate and partially divides and shears the ozone mixed water.

Here, flanges 172a and 174a for pipe connection are formed at the front end of the inlet reduction tube 172 constituting both ends of the plate-shaped mixing reactor 170 and the rear end of the rear pipe 174.

The inflow reduction tube 172 is formed to gradually decrease in diameter from the front end to the rear end to accelerate the flow rate of the ozone mixed water to be transported and change the flow path to promote the contact reaction between the raw water and the ozone gas.

Protruding member 176 is provided so that a plurality of evenly disposed on the inner surface of the rear pipe 174, the ozone mixed water to be transported impacts the plurality of protruding members 176, the direction and flow rate is changed and turbulent phenomenon In addition to this, part of the separation and shearing, the contact reaction between the raw water and the ozone gas is promoted again.

The protruding member 176 may be implemented in the form of an inclined small plate, as shown.

The multiple injection reactor 180 accelerates, splits, shears, vortices, turbulences, and flows back while continuously conveying the ozone mixed water treated in the plate mixing reactor 170 to promote the contact reaction again.

As shown in FIG. 4, the multi-injection reactor 180 includes a main pipe 182 for internally transferring ozone mixed water supplied from the plate-shaped mixing reactor 170 and a flow direction of ozone mixed water in the main pipe 182. It is formed in the form of a plate that is repeatedly provided in a direction orthogonal to the blocking porous plate 184 having a plurality of through holes (184a).

Here, both ends of the main pipe 182 is open, and both ends are formed with a flange portion 182a for pipe connection.

The blocking porous plate 184 is repeatedly provided to be spaced apart along the longitudinal direction of the main pipe 182.

Therefore, the ozone mixed water to be transported sequentially hits the blocking porous plate 184 and the flow is changed or reversed, or the flow rate is changed, and the flow rate is accelerated and partly divided while passing through the through hole 184a. The action and the vortex, turbulence, and countercurrent action can promote the contact reaction between the raw water and the ozone gas.

While the multiple injection reactor 180 is about 10 times better reaction efficiency than the existing static mixer, etc., the energy consumption is very low to 83% level can significantly reduce the energy use.

In summary, the distribution of ozone gas in the raw water becomes very uniform while passing through the membrane gas injector 140 and the plate-shaped mixing reactor 170, and the contact reaction between the raw water and the ozone gas becomes full while passing through the multiple injection reactor 180. .

The split shear reactor 190 promotes the contact reaction again by splitting, shearing, inverting, and turbulizing while continuously transporting the ozone mixed water treated in the multiple injection reactor 180.

As shown in FIG. 5, the split shear reactor 190 is perpendicular to the main pipe 192 and the main pipe 192 in the main pipe 192 to transfer the ozone mixed water supplied from the multiple injection reactor 180. It consists of a spiral blade 194 in the form of a curved plate that is provided so that the direction of the direction and the horizontal direction is repeated to divide and continue dividing the ozone mixed water.

Here, both ends of the main pipe 192 is open, the flanges 192a for pipe connection are formed at both ends thereof.

Accordingly, the ozone mixed water transported inside is continuously divided so as to pass through each spiral blade 194, and its direction and flow rate vary according to the curved shape of the spiral blade 194, and each spiral blade 194. ) Is reversed and converted as the direction of the sequential changes, thereby promoting the contact reaction between the raw water and the ozone gas by the strong shear and turbulent action.

Here, if the number of spiral blades 194 is n, the number of ozone mixed water is divided into 2 kPa.

This split shear reactor 190 causes rather large energy usage but is good in terms of reaction efficiency.

The plate-type mixing reactor 170, the multi-injection reactor 180, and the split shear reactor 190 as described above are all low-energy type gas-liquid contact reactors that can significantly reduce the energy use of the ozone mixed water as compared to the existing static mixers. Whether the three kinds of reactors 170, 180, 190 are adopted, the order of placement, and the number of units provided may be optional.

The main reactor 230 facilitates the contact reaction between raw water and ozone gas which has not yet been reacted through the plate mixing reactor 170, the multiple injection reactor 180, and the split shear reactor 190 to almost complete the reaction. .

The main reactor 230 essentially includes the injection reverse mixing reactor 200, and optionally includes the low-energy used gas-liquid contact reactor in front of the injection reverse mixing reactor 200.

The drawing shows the case where the split shear reactor 190 is employed as a low energy use gas-liquid contact reactor embedded therein.

The main reactor 230 has a relatively large diameter and a reaction tank 210 for accommodating and then discharging the treated water discharged from the injection reverse mixing reactor 200, and a split shear reactor embedded in the reaction tank 210 ( 190, and a jet reverse mixing reactor 200, and gas-liquid separation means 220 for separating and discharging exhaust gas such as oxygen gas remaining in the ozone mixed water accommodated in the reaction tank 210.

Here, the injection reverse mixing reactor 200 again promotes the contact reaction through injection and countercurrent mixing.

As shown in FIG. 6, the injection reverse mixing reactor 200 has a front end side into which the ozone mixed water is introduced and a rear end side from which the outflow end is gradually reduced in cross section so that the injection hole 222b is formed at the center thereof. And a concave concave reflector plate 224a for backflowing the ozone mixed water injected from the spray pipe 222, and a rear pipe having a discharge port 224b for discharging the treated water reacted on one side wall. Consisting of 224.

Here, the tip of the injection pipe 222 is open, the flange portion 222a for pipe connection is formed at the tip.

Therefore, when the ozone mixed water supplied from the split shear reactor 190 is injected from the injection hole 222b through the inside of the injection pipe 222, the direction and flow rate of the ozone mixed water are changed to generate turbulent action. When the injected ozone mixed water passes through the inside of the rear pipe 224 and hits the concave reflector 224a, turbulent flow, vortex flow, and backflow action are generated, and the contact reaction is promoted. It is discharged through the outlet 224b formed at one side wall of the 224 and is received into the reaction tank 210.

This injection reverse mixing reactor 200 is also a low-energy used gas-liquid contact reactor that can reduce the energy loss of ozone mixed water as compared to conventional static mixers.

The gas-liquid separating means 220 maintains the pressure in the reaction tank 210 by discharging exhaust gas such as oxygen gas generated according to the gas-liquid contact reaction and remaining in the treated water from the treated water in the reaction tank 210. .

The gas-liquid separating means 220 may be implemented as a check valve that can selectively discharge the exhaust gas collected in the upper space in the reaction tank 210.

The discharge pipe 240 continuously discharges the treated water discharged from the reaction tank 210 of the main reactor 230 and extends from the reaction tank 210.

The discharge pipe 240 is designed and provided to minimize the energy loss of the treated water to be transferred.

Furthermore, according to the present invention, the treated water may be discharged by being transported to the desired location through the discharge pipe 240, and preferably, the discharge tank to finally collect and store the treated water discharged through the discharge pipe 240. 270 may be further provided.

Discharge tank 270 is to collect the final treated water to be safely discharged, it is selected as the capacity to overcome the inflow and outflow fluctuations of the treated water and operate the system stably.

In addition, a pressure maintaining means 250 may be provided on the discharge pipe 240 in order to minimize the pressure drop in the main reactor 230 as the treated water is discharged through the discharge pipe 240.

The pressure maintaining means 250 may be implemented through a structure to reduce the internal flow path of the discharge pipe 240.

In addition, by spraying the treated water into the water in the discharge tank 270 to discharge the treated water to the end of the discharge pipe 240 in order to allow the treated water to be finished reaction in the discharge tank 270 using residual energy and ozone. 260 may be provided.

As described above, the configuration that continues in one line form from the raw water tank 110 to the discharge tank 270 is for a method of processing once while continuously transferring the raw water.

On the other hand, according to the present invention, it is also possible to implement a method of repeating two or more times in accordance with the raw water quality and treatment goals, the configuration of such a repeating method is shown in FIG.

In the repetitive treatment method, a circulation pipe 280 is branched in the middle of the discharge pipe 240 for transferring the treated water from the main reactor 230 to the discharge water tank 270 to circulate a portion of the treated water to the raw water tank 110. This is further provided.

That is, the treated water transferred after the reaction treatment in the main reactor 230 is divided into the discharge pipe 240 and the circulation pipe 280 on the way, and is supplied to the discharge water tank 270 and the raw water tank 110, respectively.

In addition, the raw water tank 110 is mixed feeder so that the treated water supplied through the circulation pipe 280 and the raw water supplied from the raw water tank 110 for reprocessing may be supplied together to the water supply pipe 120. 290 is further provided.

As shown in FIG. 8, the mixing feeder 290 includes a mixing pipe 292 formed with a large diameter portion having a large diameter portion introduced therein and integrated with a small diameter portion having a relatively small diameter portion flowing out therein. It is composed of a strainer (294) is provided in the central portion in the large diameter portion to cover the inlet side to filter the foreign matter contained in the treated water and the raw water transported inside.

Accordingly, the end of the circulation pipe 280 is inserted into the large diameter portion of the mixing pipe 292 and contacts the strainer 294 to supply the treated water directly to the strainer 294, and the large diameter portion and the strainer of the mixing pipe 292. The raw water in the raw water tank 110 is supplied through the space between the 294 to be mixed with the treated water and the raw water and then supplied to the water pipe 120.

In addition, although not shown, the ozone water treatment system according to the present invention may further include a control panel for performing overall operation control to enable automatic operation, wherein the water supply pipe 120, the ozone supply pipe 165, the source gas supply pipe 155, the discharge pipe 240 and the circulation pipe 280, valve means (V) for opening and closing the supply of the fluid, the hydraulic system (P) and flow meter (F) for measuring the pressure and flow rate of the fluid It may be provided.

In addition, the size, number, structure, and the like of each element and its associated elements may be appropriately determined in consideration of raw water quality and quantity, target water quality, ozone gas injection amount, and the like.

The operation of the ozone water treatment system using the low energy according to the present invention having the above configuration will be described below.

First, when the water pump 130 is operated, the raw water of the treatment object stored in the raw water tank 110 is sucked and transported through the water supply pipe 120 and then supplied to the membrane gas injector 140.

At this time, the raw water is given energy required for water treatment by the water pump 130.

Of course, without using the water pump 130, the raw water may be given potential energy due to a drop and supplied through the water pipe 120.

Subsequently, raw water supplied to the membrane gas injector 140 flows inside the membrane gas injector 140, at which time ozone is generated in the ozone generator 160 and then supplied through the ozone supply pipe 165 with an appropriate pressure. Gas is sprayed to be dispersed in the form of ultra-fine bubbles through the porous tube 146 in the membrane gas injector 140 and injected into the raw water flowing therein and mixed.

Thereafter, the ozone mixed water is continuously supplied to the plate-shaped mixing reactor 170 and accelerated, turbulent, split, and sheared in the plate-shaped mixing reactor 170 to perform a contact reaction between the raw water and the ozone gas.

Subsequently, ozone mixed water is continuously supplied to the multi-jet reactor 180 to accelerate, split, shear, vortex, turbulence, and backflow the multi-jet reactor 180 so that contact reaction between the raw water and the ozone gas is performed again.

Subsequently, the ozone mixed water is continuously supplied to the split shear reactor 190 to be split, sheared, inverted, and turbulized in the split shear reactor 190, whereby the contact reaction is performed again.

Thereafter, the ozone mixed water is once again promoted while passing through the multiple injection reactor 180 and then supplied to the main reactor 230.

The ozone mixed water supplied to the main reactor 230 is passed through the split shear reactor 190 embedded in the main reactor 230 to promote the reaction again, and then is supplied to the injection reverse mixing reactor 200 to supply the injection reverse mixing. In the reactor 200, the reaction is accelerated, turbulent, vortex, and countercurrent again.

Then, the ozone mixed water discharged from the injection reverse mixing reactor 200 is discharged into and received in the reaction tank 210 of the main reactor 230, and the exhaust gas remaining in the treated water while staying in the reaction tank 210. The gas is separated and discharged by the gas-liquid separating means 220 and removed.

Thereafter, the treated water almost completed by the main reactor 230 is discharged from the reaction tank 210 of the main reactor 230 and then transferred through the discharge pipe 240, and then It is discharged into the water in the discharge tank 270 through the injection means 260 provided at the end, and then finish reaction using residual energy and residual ozone in the discharge tank 270.

In the case of the repetitive treatment method, a part of the treated water transferred through the discharge pipe 240 is divided into a circulation pipe 280 branched on the way, and is supplied to the raw water tank 110, and the treated water circulated for reprocessing. Is sucked with the raw water in the mixing feeder 290, mixed and then fed back through the water pipe 120.

Thus, according to the present invention, the use of the membrane gas injector 140 can significantly reduce the energy use during ozone gas injection, and also use the low energy use type gas-liquid contact reactors, which can greatly reduce the energy use during the contact reaction. As a result, processing costs can be reduced.

In addition, low energy loss type reactors such as plate mixing reactor 170, multiple injection reactor 180, split shear reactor 190 and injection reverse mixing reactor 200 may be used in combination, and a portion of the treated water may be By recirculating and reprocessing, perfect water treatment can be achieved.

And, the processing time required to go through the entire process can also be shortened by about 1/10 compared to the conventional diffuser method, it can also be excellent in the processing productivity.

In the foregoing description, it should be understood that those skilled in the art can make modifications and changes to the present invention without changing the gist of the present invention as merely illustrative of a preferred embodiment of the present invention.

1 is a block diagram of an ozone water treatment system using a low energy according to a preferred embodiment of the present invention,

2 is a schematic cross-sectional view of a membrane gas injector of an ozone water treatment system using low energy according to a preferred embodiment of the present invention;

3 is a partial cutaway cross-sectional view of a plate-shaped mixing reactor of an ozone water treatment system using low energy according to a preferred embodiment of the present invention;

4 is a cross-sectional view of a multiple injection reactor of an ozone water treatment system using low energy according to a preferred embodiment of the present invention;

5 is a schematic cross-sectional view of a split shear reactor of an ozone water treatment system using low energy according to a preferred embodiment of the present invention;

6 is a cross-sectional view of a spray reverse mixing reactor of an ozone water treatment system using low energy according to a preferred embodiment of the present invention;

7 is a block diagram of an ozone water treatment system using a low energy according to another embodiment of the present invention,

8 is a schematic cross-sectional view of a mixed feeder of an ozone water treatment system using low energy according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

110: raw water tank 120: water pipe

130: water pump 140: membrane gas injector

142: gas connector 144: main pipe

144a: flange 146: porous tube

146a: injection hole 150: raw material gas tank

155: source gas supply pipe 160: ozone generator

165: ozone supply pipe 170: plate mixing reactor

172: inflow reduction tube 172a: flange portion

174: rear piping 174a: flange

176: protrusion member 180: multiple injection reactor

182: main pipe 182a: flange

184: blocking plate 184a: through hole

190: split shear reactor 192: main piping

192a: flange 194: spiral blade

200: injection reverse mixing reactor 222: injection piping

222a: flange portion 222b: injection hole

224: rear pipe 224a: concave reflector

224b: outlet 210: reaction tank

220: gas-liquid separation means 230: main reactor

240 discharge pipe 250 pressure maintaining means

260: injection means 270: discharge tank

280: circulating pipe 290: mixing feeder

292: mixed piping 294: strainer

F: Flow meter P: Pressure gauge

V: valve means

Claims (19)

A water supply pipe through which raw water to be treated is transported with energy; A membrane gas injector for dispersing and injecting ozone gas into ultrafine bubbles into raw water supplied from the water pipe; A low energy usage type gas-liquid contacting reactor for promoting a contact reaction between the raw water and the ozone gas in the ozone mixed water supplied and transported from the membrane gas injector; And Ozone water treatment system using a low energy comprising; a discharge pipe for continuously transporting the discharged treated water. The method of claim 1, The low energy used gas-liquid contact reactor, An ozone water treatment system using low energy, characterized in that it consists of any one or more combinations selected from a plate mixing reactor, a multiple injection reactor, and a split shear reactor. The method according to claim 1 or 2, The raw water supplied through the water pipe, An ozone water treatment system using low energy, which is pressurized and transported by potential energy caused by a drop. The method according to claim 1 or 2, An ozone water treatment system using low energy further comprising; a water supply pump for supplying energy to the raw water and returning the energy. The method according to claim 1 or 2, An ozone water treatment system using low energy further comprising; a raw water tank for storing the raw water and supplying the raw water. The method according to claim 1 or 2, An ozone generator for generating and supplying the ozone gas to be supplied to the membrane gas injector; And An ozone water treatment system using low energy further comprising; an ozone supply pipe for transferring the ozone gas supplied from the ozone generator to the membrane gas injector. The method according to claim 1 or 2, A discharge tank for storing the treated water discharged from the discharge pipe; And Spraying means provided at the end of the discharge pipe for injecting the treated water into the water in the discharge tank, ozone water treatment system using a low energy. The method according to claim 1 or 2, A main reactor for promoting a contact reaction between the raw water and the ozone gas in the ozone mixed water supplied from the low-energy used gas-liquid contacting reactor and supplying the treated water to the discharge pipe. Ozone water treatment system. The method of claim 2, The low energy used gas-liquid contact reactor, The ozone water treatment system using low energy, characterized in that the plate-type mixing reactor, the multiple injection reactor, the split shear reactor, the multiple injection reactor. The method of claim 8, The main reactor, A spray reverse mixing reactor in which the ozone mixed water is injected and countercurrently mixed to cause a contact reaction; And And an internal reaction tank configured to accommodate the treated water discharged from the injection reverse mixing reactor and then discharge the reaction reverse mixing reactor. The method of claim 10, And a low energy use type gas-liquid contact reactor embedded in the reaction tank and contacting the ozone mixed water and then discharged to the injection reverse mixing reactor. The method of claim 11, The low energy used gas-liquid contact reactor, An ozone water treatment system using low energy, characterized in that any one or more selected from a plate mixing reactor, a multiple injection reactor, and a split shear reactor. The method of claim 10, The injection reverse mixing reactor, An injection pipe in which the front end of the ozone mixed water is introduced and the rear end of the outflow of the ozone mixed water is reduced in cross section so that injection holes are formed in a central portion thereof; And And a rear pipe having a concave reflection plate formed at a rear end thereof so as to hit the ozone mixed water injected from the injection pipe and flowing backward, and having a discharge port for discharging the treated water at one side thereof. The method of claim 1, The membrane gas injector, A main pipe for internally transferring the raw water supplied from the water pipe; And And a porous tube provided in the main pipe and spraying the ozone gas supplied through the plurality of injection holes into the water of the raw water in the form of ultra fine bubbles. The method of claim 2, The plate mixing reactor, An inlet reduction tube having a diameter gradually reduced to change a flow path and a flow rate of the ozone mixed water supplied from the membrane gas injector; A rear pipe for internally transferring the ozone mixed water supplied from the inflow reduction tube; And And a plurality of protruding members provided to protrude on the inner side of the rear pipe to change the direction and flow rate of the ozone mixed water, and to divide and shear and contact the ozone mixed water. The method of claim 2, The multiple injection reactor, A main pipe for transferring the ozone mixed water therein; And And a blocking porous plate provided in the main pipe in a direction orthogonal to the flow direction of the ozone mixed water and having a plurality of through holes through which the ozone mixed water passes. The method of claim 2, The split shear reactor, A main pipe for transferring the ozone mixed water therein; And The ozone water treatment system using low energy, characterized in that consisting of; spiral blade of the curved plate shape that is repeatedly provided along the longitudinal direction in the main pipe. The method of claim 1, A circulation pipe branched in the middle of the discharge pipe and transferring a part of the treated water to the raw water tank side for reprocessing; And And a mixed feeder for mixing the treated water supplied through the circulation pipe and the raw water supplied from the raw water tank and supplying the mixed water to the water supply pipe. The method of claim 18, The mixing feeder, A mixing pipe for mixing the treated water and the raw water while mixing the same; And And a strainer provided in the mixing pipe to filter foreign substances.

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